US7591812B1 - Passive venous air purging chamber with vent/sucker blood handling capabilities - Google Patents

Passive venous air purging chamber with vent/sucker blood handling capabilities Download PDF

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US7591812B1
US7591812B1 US11/491,853 US49185306A US7591812B1 US 7591812 B1 US7591812 B1 US 7591812B1 US 49185306 A US49185306 A US 49185306A US 7591812 B1 US7591812 B1 US 7591812B1
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blood
chamber
air
air purging
venous
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Yehuda Tamari
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    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M1/00Suction or pumping devices for medical purposes; Devices for carrying-off, for treatment of, or for carrying-over, body-liquids; Drainage systems
    • A61M1/36Other treatment of blood in a by-pass of the natural circulatory system, e.g. temperature adaptation, irradiation ; Extra-corporeal blood circuits
    • A61M1/3621Extra-corporeal blood circuits
    • A61M1/3627Degassing devices; Buffer reservoirs; Drip chambers; Blood filters
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M1/00Suction or pumping devices for medical purposes; Devices for carrying-off, for treatment of, or for carrying-over, body-liquids; Drainage systems
    • A61M1/36Other treatment of blood in a by-pass of the natural circulatory system, e.g. temperature adaptation, irradiation ; Extra-corporeal blood circuits
    • A61M1/3621Extra-corporeal blood circuits
    • A61M1/3627Degassing devices; Buffer reservoirs; Drip chambers; Blood filters
    • A61M1/3632Combined venous-cardiotomy reservoirs
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M1/00Suction or pumping devices for medical purposes; Devices for carrying-off, for treatment of, or for carrying-over, body-liquids; Drainage systems
    • A61M1/36Other treatment of blood in a by-pass of the natural circulatory system, e.g. temperature adaptation, irradiation ; Extra-corporeal blood circuits
    • A61M1/3621Extra-corporeal blood circuits
    • A61M1/3666Cardiac or cardiopulmonary bypass, e.g. heart-lung machines
    • A61M1/3667Cardiac or cardiopulmonary bypass, e.g. heart-lung machines with assisted venous return

Definitions

  • the full invention consists of an air purging system in combination with a compliant storage chamber having at least one pliable wall that forms a venous reservoir and a two-chamber cardiotomy reservoir incorporated atop the storage chamber.
  • the combined units provide a collapsible “closed” venous reservoir unitized with cardiotomy reservoir, with vented blood separated from the sucker blood, having air removal features that improve that of a hardshell venous-cardiotomy reservoir unit.
  • the innovative characteristics of each of the three devices support their use on their own.
  • VAVD Vacuum assisted venous drainage
  • VAVD allows for a decrease in the inner diameter (ID) of the venous line, thereby reducing prime volume and enabling the use of a smaller internal diameter cannula, which translates to an easier insertion, better surgical view and a smaller surgical incision.
  • venous bags are used because they provide significant safety features: if the bag accidentally empties, it collapses, thereby preventing gross air from being pumped to the patient, they have no, or very little, air-blood interface, and they require no antifoam agents that can embolize into the blood.
  • Designs that allow VAVD with venous bags have been previously described by Tamari's U.S. Pat. Nos. 6,337,049 and 6,773,426, and Cambron's U.S. Pat. No. 6,537,495.
  • the present invention also allows the user the option of VAVD.
  • the only venous reservoir that combines a flexible wall and a rigid wall to form a “closed” variable blood chamber is that described in U.S. Pat. Nos. 4,424,190 and 4,959,062.
  • Each of these devices has its outlet at the lowest point of the venous reservoir (see 24 in FIG. 24 of U.S. Pat. No. '062, and 36 in FIG. 3 of U.S. Pat. No. '190).
  • This choice makes it more difficult to assure that the pliable wall seals against its mating rigid wall when the reservoir empties.
  • the '190 patent has a drawback: once that reservoir empties, its pliable wall is sucked in at its outlet and shuts off as it should.
  • the '062 patent's design alleviates that flaw however it introduced another problem: when the reservoir empties the rib prevents the flexible wall from completely sealing against the outlet port allowing air from the cardiotomy reservoir to be sucked in, an undesirable outcome.
  • the present invention provides a design that allows the outlet to close completely when the reservoir empties and to easily open when less than 1 ⁇ 3 of the volume of a full reservoir returns.
  • Hard shell reservoirs have defoamers within the venous inlet chamber (e.g. see defoamer 6 in distribution chamber 22 of FIG. 1 in Fini, U.S. Pat. No. 6,287,270).
  • defoamer 6 in distribution chamber 22 of FIG. 1 in Fini, U.S. Pat. No. 6,287,270 In the open, hard shell reservoir, air escapes by floating to the top of the reservoir where it is purged to atmosphere.
  • air In prior art venous bag reservoirs, air also floats to the top but it must be actively eliminated. This can be done manually with a syringe, or more frequently with a roller pump intermittently operating to remove air accumulating at the top of the bag. This is shown in FIG.
  • Tamari's '049 and '426 patents also describe a blood chamber with a level sensor that activates a vacuum source to remove the air when the blood level in the chamber drops below that sensor.
  • the design provides automated means to remove air from that chamber and that chamber in combination with a blood chamber having at least one flexible wall allows automated air removal and VAVD with a venous bag but does not, as the present invention, allow for passive air removal.
  • FIG. 1 a a line drawing of a prior art bag made by Cobe
  • FIG. 1 aa a line drawing of a cross section along line 1 aa - 1 aa ′ of the bag shown in FIG. 1 a
  • FIG. 1 ab an enlargement of the circled section of the bag shown in FIG. 1 aa .
  • at low volume most of the screen contacts the walls of the bag and is unavailable for blood flow.
  • the preferred screen used for State-of-the-Art venous bag has a pore size of 105 ⁇ and an open area of 52% as compared to an open area of only 30% for a screen with a pore size of 37 ⁇ .
  • the use of smaller pore screen reduces the size and number of bubbles.
  • the larger effective screen area of the present invention allows using a smaller pore size screen and still maintaining a total open area that is equal to, or is even larger than, State-of-the-Art bags thereby maintaining a blood velocity across the screen that equals to or is lower than that associated with current bags. A lower velocity translates to lower number of bubbles crossing the screen.
  • the present invention provides more reliable means to alarm at low blood levels.
  • a softshell reservoir with integrated cardiotomy reservoir is described in Elgas's U.S. Pat. No. 5,935,093. That softshell blood reservoir incorporates an integral flexible cardiotomy section in which a filter/defoamer unit is supported in a semirigid cage. The reservoir also incorporates a storage section and a mixing section. The three sections can selectively communicate with each other.
  • a major shortcoming of this unit is that if the cardiotomy, in fluid communication with the venous reservoir, empties, then air can enter the venous reservoir and exit its outlet. The unit also does not allow VAVD and requires active removal of air from the venous reservoir. The present invention prevents air from the cardiotomy to exit the venous reservoir, allows VAVD and air is exhausted to atmosphere passively.
  • the present invention provides the user with a collapsible venous reservoir and a cardiotomy reservoir as a single unit that is easy to setup, and is clinically safer than the State-of-the-Art unified hard shell venous-cardiotomy reservoir unit.
  • clean blood includes blood aspirated from a venting site (e.g. the aortic root cardioplegia cannula, LV vent), blood with entrapped air withdrawn from the top of a venous bag (i.e. as used by NovoSci), and blood purged from the top of the arterial filter.
  • a venting site e.g. the aortic root cardioplegia cannula, LV vent
  • entrapped air withdrawn from the top of a venous bag
  • i.e. as used by NovoSci i.e. as used by NovoSci
  • Clean blood is distinctly different from the “dirty” blood sucked from the surgical field, mostly of which comes from the pericardial sack.
  • Vent blood may entrain a large volume of air.
  • 6,908,446 illustrates a cardiotomy reservoir with a filter for the vented blood and a separate filter for dirty blood. This prevents clean blood from directly contacting foreign substances filtered off from the dirty blood but does not prevent clean blood accumulating in the cardiotomy from contacting the debris in the filter once the blood level reached the debris.
  • the present invention addresses these drawbacks by separating the clean blood from the dirty blood as well as giving the user a choice to return the dirty blood to the bag or to a cell saver.
  • the former separates blood from air as it enters the reservoir but results in foam from the entering blood splashing into the blood in the reservoir.
  • the latter when the blood level is above the outlet of the entrance tube, results in foam from the air in the entering blood bubbling in the blood in the reservoir.
  • the present invention allows at least the clean blood to enter along an angle that purges most of the air prior to the clean blood joining blood already in the cardiotomy while limiting splashing.
  • Cardiotomy reservoirs are also used to accommodate the overflow of blood volume that exceeds the capacity of the venous bag (the largest one can accommodate less than 2.0 L). Larger blood volume capacity is frequently required during aortic or mitral valve replacement during which the excess volume rises into the cardiotomy reservoir resulting in clean venous blood contacting the aggressive filter and the filtrate (e.g. fat, bone chips etc.) trapped at the bottom of the filter of the cardiotomy reservoir that can result in the aforementioned undesirable outcomes.
  • the filtrate e.g. fat, bone chips etc.
  • the blood level at which the clean blood contacts the antifoam loaded defoamer in the venous reservoir and the volume at which the blood contacts the aggressive cardiotomy reservoir filter is summarized in Table 1 for typical State-of-the-Art hard shell venous-cardiotomy reservoir units.
  • the volume capacity of the closed venous blood chamber and/or the “clean” chamber of the cardiotomy reservoir is higher than current systems, thereby limiting clean blood contact with the “dirty” chamber and/or defoamer while limiting blood-to-air interface (see below).
  • Minimizing the blood-to-air interface is a major design objective of devices used in the cardiopulmonary bypass circuit.
  • the last two columns in Table 1 provide the surface area of air that the blood is exposed to when the reservoir contains 500 or 1000 ml of blood.
  • the venous reservoir of the present invention when filled, it has 7 to 30 times smaller blood-to-air area than State-of-the-Art hard shell venous reservoirs. The values assume that there is no air in the venous blood or foam above the blood. It should be noted that the maximum venous blood volume that can be accommodated by the State-of-the-Art units without contacting the defoamer, of either the HSVR or CR, or the dirty blood filter is 1,200 ml.
  • the defoamer of State-of-the-Art venous reservoirs is located at least along the top section of the reservoir (e.g. Terumo's SX-25) or lineup the entire screen area of the inlet section of the reservoir (Cobe's VVR 4000i).
  • One aspect of the present invention incorporates a top and bottom defoamer, wherein the bottom defoamer is smaller by volume and extends downward from the top defoamer into the inlet chamber of the air purging chamber, a geometry that provides flexibility in adjusting early defoaming capabilities while reducing the defoamer contact with the blood.
  • Blood flow from the cardiotomy reservoir to a venous bag can be intermittent or continuous depending on the frequency the suckers are used and the volume aspirated from the field.
  • the outlet port of the cardiotomy reservoir used for adults is universally 3 ⁇ 8′′ internal diameter as is the tube connecting the outlet of the cardiotomy reservoir to the inlet of the venous bag (see tube 153 in FIG. 1 ). Further, the outlet port faces straight vertically or horizontally. That combination results in the air in tube 153 to be trapped by the incoming blood above it, and dragged with that blood into the venous bag thereby adding air to the blood in the venous bag.
  • a form of the present invention provides a fluid path between the cardiotomy reservoir and venous bag with decreased tendency to trap air.
  • FIGS. 8 c and 8 d also show that the values of the dimensionless parameter for the present invention (i.e. APC and VR+APC) are significantly higher than Terumo's values. For that reason, as well as others described below, the present invention handles air better than any other State-of-the-Art venous reservoir.
  • Hard shell venous reservoirs utilize low level detectors to either shut the arterial pump and/or actuate a tubing clamp (e.g. see Sorin's ECC.O system below) to stop outlet flow from the reservoir and prevent the reservoir from emptying and air from being pumped to the patient.
  • a higher change in blood level per change in volume i.e. a reservoir with smaller cross sectional area
  • Terumo's hard shell venous reservoirs have the smallest cross sectional area with the highest blood level of any State-of-the-Art reservoirs.
  • Terumo's reservoirs also have the largest screen area and smallest blood-to-air interface, see FIG. 8 d .
  • the present invention improves on these parameters, providing an elongated, small diameter air purging chamber with a larger screen area and smaller blood-to-gas interface per blood volume.
  • Terumo's minicircuit includes an air sensor that controls both the centrifugal pump and an electronic venous occluder that allow the user to remove the air manually. Stopping blood flow to remove air may be clinically harmful, especially in cases where air enters the venous line repeatedly.
  • Medtronic's, CardioVention's and Cobe's minicircuits utilize a sensor that detects air in the venous line and actuates suction to remove that air and the associated electronics assure that the suction is applied only when so indicated by the sensor. Doing otherwise removes blood from the reservoir or risking air entering the outlet of the air purging chamber.
  • a more recent invention is described by Olsen et al in US Patent Application number 20040220509 entitled “Active air removal from an extracorporeal blood circuit”. That design requires complicated electronics as displayed by FIGS. 14 through 56 of that application.
  • a form of the present invention provides efficient venous air removal unmatched by any minicircuit, or State-of-the-Art hard shell or soft shell reservoirs.
  • the air purging chambers of State-of-the-Art minicircuits essentially placed arterial filters in the venous line. These filters' ratio of height to diameter is less than 2 and they do not communicate with ambient atmosphere. This design is not conducive to detecting small changes in volume.
  • the present invention provides a much larger height to diameter ratio and a much larger change in height for the same change in volume, a characteristic that allows level sensors to react to much smaller volume changes.
  • a major objective for “venous filters” with air removal capabilities is to reduce the priming volume of the CPB circuit by removing the venous reservoir while still removing air and foam from the venous line prior to it entering the arterial pump.
  • At least one aspect of the present invention provides further reduced volume and effectively, passively or actively, deaerates venous blood and collapses foamed blood, much like hard-shell venous reservoirs do. This action is achieved without the need to reduce pump flow or suck blood out of the circuit, and requires less contact with the defoamer while lowering foam volume (by defoaming the blood earlier), without exposing venous blood to the “dirty” blood of a cardiotomy, and with minimal or no blood loss due to air removal.
  • the present invention deaerates clean blood before it is combined with venous blood without requiring it to pass through either a cardiotomy reservoir or a cell saver. In one form this is achieved with a two chamber cardiotomy, one chamber for the dirty blood and the other for the clean blood, with means that allow the user to start or stop blood flow from the dirty to the clean blood. Blood from the clean blood chamber is in fluid communication with the inlet of the venous reservoir.
  • KAVD Kerman Assisted Venous Drainage
  • Centrifugal pumps handle air poorly; any large bubbles that pass the air-removal system and enter the centrifugal pumps are divided into much smaller bubbles that are less buoyant and are thus more difficult to remove. Large bubbles that could be trapped at the top of the arterial filter appear as smaller bubbles, able to cross the arterial filter. This problem is further exacerbated at the higher pump speeds needed when a single centrifugal pump is used both to draw venous blood and to generate the arterial line pressure. 2. Centrifugal pumps maintain a fixed pressure difference between inlet and outlet. Thus, when the heart is manipulated causing the venous cannula to temporarily obstruct, venous flow stops.
  • Flow cessation due to occlusion upstream of the pump inlet results in an inlet suction at least equivalent to the positive pressure at the centrifugal pump's outlet before the flow stopped.
  • an obstruction at the pump inlet would translate to the pump generating an inlet pressure of ⁇ 250 mmHg or higher.
  • a high transient suction applied at the tip of the venous cannula could suck the vessel against the cannula's open end, causing it to occlude, preventing further flow, and perhaps causing both intima and blood damage until the pump is stopped.
  • the present invention operates in the safer VAVD mode that allows the user to set a maximum negative pressure with a vacuum regulator yet allow reverting to operating in the KAVD mode.
  • the system provides better air handling than current venous reservoirs or removes air from the venous blood before it reaches the bubble dispersing centrifugal pump.
  • the presence of air at the top of the air purger of the present invention provides compliance that reduces the spikes of negative pressure inherent with current KAVD minicircuits by allowing the pump controller more time to decrease pump flow and absorbing the large pressure spikes associated with sudden stoppage of blood flow at the pump inlet.
  • the present invention besides providing a choice between KAVD and VAVD, also allows venous drainage by gravity. Further in gravity mode it may incorporate passive means that prevent blood from spilling over the top of the blood chamber.
  • the present invention in its simplest form consists of a very efficient, low volume, chamber that removes air from the venous line, hereinafter referred to as the air purging chamber (APC).
  • the air purging chamber consists of a vertical blood chamber having an inlet, an outlet and an air purge port.
  • the inlet and outlet preferably separated by a screen that allows blood to cross from the inlet to the outlet but retains air bubbles in the inlet chamber.
  • the screen also defines an inlet chamber and an outlet chamber. Gas (e.g. air) bubbles in the blood entering the bottom of the inlet chamber rise to the top of the blood column contained by the inlet chamber and are purged to atmosphere.
  • Gas e.g. air
  • the air purging chamber separates air bubbles from the venous blood and purges that air to atmosphere as is the case with the hard shell venous reservoir without the need for the suction or vacuum required with prior State-of-Art soft-shell venous reservoir or minicircuits.
  • a defoamer located at the top of the inlet chamber, collapses foam that forms by the air bubbles in the blood.
  • the blood in the inlet chamber flows across the screen into the outlet chamber and downward towards the outlet port located along the bottom of the outlet chamber.
  • this air purger with a cardiotomy reservoir and a reservoir having at least one flexible wall as a single unit provides venous reservoir with superior air removal characteristics, with the safety benefits of prior art collapsible venous reservoirs while avoiding such disadvantages as air entrapment, required vigilance for air removal, poor level control, slower priming, and lack of a cardiotomy reservoir.
  • the functionality of this innovative venous reservoir is further enhanced by also providing VAVD capabilities with a built-in vapor trap, a small blood-to-gas interface even when the venous reservoir is full.
  • the innovative cardiotomy with a separate chamber for clean blood and separate chamber for dirty blood and a vapor trap completes this superior design.
  • the top of the air purging chamber is designed to also accept deaerated vented blood without it contacting the dirty blood in the cardiotomy reservoir.
  • the top of the air purging chamber also incorporates means to deaerate and defoam vented blood without it mixing with the dirty blood in the cardiotomy reservoir.
  • the present invention provides an improved venous air purging chamber with defoaming capabilities.
  • Yet another objective of the present invention is to provide an improved low volume venous air purging chamber with a large effective screen area available for blood flow that provides defoaming capabilities and that, in one form, accepts clean blood without that blood being exposed to dirty blood.
  • Yet another objective of the present invention is to provide an improved venous air purging chamber with a large effective screen area available for blood flow having a lower operating volume than State-of-the-Art air purgers used for minicircuits.
  • Yet another objective of the present invention is to provide an improved passive venous air purging chamber having a large effective screen area and a low operating volume that for the adult patient its blood-to-air interface area is lower than 30 cm 2 for at least 8 cm of its lower height and or 60 cm 2 for at least 13 cm of its lower height.
  • Another objective is to provide a venous air purger acting as a venous reservoir that provides a “tall” and relatively narrow liquid column having a ratio of height to diameter greater than 2 such that even at low blood volumes a large screen area is still available for blood flow and, relative to State-of-the-Art reservoirs, large changes in height correspond to small changes in volume.
  • a blood chamber with defoaming capabilities that incorporates a top and bottom defoamer, wherein the bottom defoamer has a lower volume, is longer and extends downward into the blood chamber.
  • Such chamber can for example be the venous air purging chamber.
  • Another objective is to provide a cardiotomy reservoir having at least a clean blood and a dirty blood chambers as a single unit with the clean and dirty chambers in a fluid communication that can be closed or opened by the end user.
  • Another objective is to provide fluid communication between the outlet of an air purging chamber and the inlet to a compliant storage chamber that is, at least in part, formed of the rigid structure.
  • Another objective is to provide a compliant blood chamber that once primed remains air free.
  • Another objective is to provide a compliant storage chamber with at least one pliable wall that once primed, it shuts off prior to air entering it.
  • Another objective is to provide a fluid path between an air purging chamber and a compliant storage chamber with an adjustable resistance to liquid flow thereby allowing the user to adjust the height of the blood column in the air purging chamber and thereby increase the screen area available for blood flow.
  • Yet another objective of the present invention is an improved venous blood reservoir, having at least one pliable wall combined with a cardiotomy reservoir in fluid communication such that a single air port can be used to apply the same vacuum to the blood in each of the chambers.
  • One more objective of the present invention is to incorporate a vapor trap in the vacuum side of the air purging chamber, the cardiotomy reservoir or compliant blood chamber, said trap replacing a stand alone vapor trap thereby reducing cost and setup time.
  • Another objective of the present invention is to provide an improved venous blood reservoir with at least one pliable wall having passive means to eliminate air.
  • Yet another objective of the present invention is to provide a venous reservoir with at least one flexible wall combined with a cardiotomy as a single unit that can be used with either gravity drainage or with VAVD thus, reducing cost of inventory and simplifying the user's set up.
  • a further objective of the present invention is to provide a single unit composed of a venous blood reservoir having at least one pliable wall in fluid communication with at least a second blood chamber said second chamber having at least one rigid wall wherein the blood level in the second chamber can be higher than the blood level of the chamber with the pliable wall.
  • a further objective of the present invention is to provide a venous blood reservoir having at least one pliable wall and at least second blood chamber having at least one rigid wall wherein the second chamber is located above the venous reservoir and the chambers combined as a single unit with an outlet that, once primed, shuts off before air can exit its outlet.
  • a further objective of the present invention is to provide a venous blood reservoir and a cardiotomy reservoir combined as a single unit with the venous blood reservoir able to handle a blood flow of 6 l/min and accommodates at least 1,300 ml without the venous blood contacting a defoamer and/or the filter of the dirty blood.
  • a further objective of the present invention is to provide a venous blood reservoir having at least one pliable wall and a cardiotomy reservoir combined as a single unit and with the cardiotomy consisting of a clean blood chamber and a dirty blood chamber, said cardiotomy chambers in fluid communication with each other via a fluid path that can be opened/closed by the user.
  • a further objective of the present invention is to provide a cardiotomy reservoir consisting of a clean blood chamber and a dirty blood chamber; said chambers in fluid communication with each other, and means that allow the user to open/close said fluid communication.
  • a further objective of the present invention is to provide a blood path between the outlet of a cardiotomy reservoir and a second chamber that incorporates means that limit the volume of air entrapped and pumped from the cardiotomy reservoir into the second chamber.
  • a further objective of the present invention is to provide a venous blood reservoir with improved passive air removal capabilities, having a blood volume capacity of at least 300 ml and a flow capacity of at least 5 l/min, wherein the venous blood-to-air interface is no more than 50 cm 2 for at least the lower 10 cm of the blood reservoir.
  • a further objective of the present invention is to provide a stand-alone venous air purging chamber with passive and improved passive air removal capabilities even when operating at a blood volume less than 150 ml that can handle a blood flow of at least 4 l/min.
  • Yet another objective is to offer the combination of a rigid air purging chamber and a venous reservoir having at least one flexible wall with passive air removal capabilities.
  • One more objective of the present invention is to provide a venous air purging chamber with passive and improved air removal capabilities having a ratio of screen area to blood-to-air-interface area of at least 4.0.
  • Another objective of the present invention is to provide the manufacturing flexibility to accommodate future clinical finding that could determine which is more beneficial to the patient: collapsing the foam to reduce blood-gas interface or reducing blood contact with the defoamer.
  • FIG. 1 is a line drawing of the pertinent components of a typical cardiopulmonary bypass circuit showing the prior art soft shell venous reservoir and a single chamber cardiotomy reservoir.
  • FIG. 1 a is a line drawing illustrating that at a low blood level in a prior art venous bag the effective screen area is very small relative to total area of the screen in the bag and that suction is required to remove air entering the bag.
  • FIG. 1 aa is a line drawing of a cross section along line 1 aa and 1 aa ′ of prior art bag shown in FIG. 1 a illustrating that at low blood volume very little of the screen of this bag is available for blood flow.
  • FIG. 1 ab is a line drawing of an enlargement of the circled section of the bag shown in FIG. 1 aa showing that at low volume with the prior art bag very little of the screen is available for blood flow.
  • FIG. 2 is a line drawing of the pertinent components of a typical cardiopulmonary bypass circuit showing the soft shell venous reservoir integrated with the air purging chamber and a two chambered cardiotomy reservoir of the present invention.
  • FIG. 3 a is a line drawing of the front view of one preferred embodiment of the present invention illustrating a venous air purging chamber that purges air without the user input.
  • FIG. 3 aa is a line drawing illustrating a means to prevent blood from overfilling the air purging chamber using a vertically extended air exhaust tube.
  • FIG. 3 b is a line drawing illustrating another view of the air purging chamber illustrated in FIG. 3 a taken along line 3 b - 3 b ′ of FIG. 3 a.
  • FIG. 3 c is a line drawing of the front view of another preferred embodiment of the present invention illustrating a venous air purging chamber similar to that illustrated in FIG. 3 a that also incorporates a deaerating and defoaming chamber for vented (clean) blood.
  • FIG. 3 d is a line drawing illustrating another view of the air purging chamber illustrated in FIG. 3 c taken along line 3 d - 3 d ′ of FIG. 3 c.
  • FIG. 4 a is a line drawing illustrating one preferred embodiment of the present invention where the air purging chamber shown in FIG. 3 a is combined with a venous reservoir having at least one flexible wall and with the innovative two-chambers cardiotomy reservoir.
  • FIG. 4 b is a line drawing illustrating another cross sectional view of the air purging chamber combined with the venous and the two chambers cardiotomy reservoir illustrated in FIG. 4 a taken along line 4 b - 4 b ′ of FIG. 4 a.
  • FIG. 4 c is a line drawing illustrating another cross sectional view of the air purging chamber combined with the venous and cardiotomy reservoir illustrated in FIG. 4 a taken along line 4 c - 4 c ′ of FIG. 4 a.
  • FIG. 4 d is a line drawing illustrating another cross sectional view of the air purging chamber combined with the venous and cardiotomy reservoir illustrated in FIG. 4 a taken along line 4 d - 4 d ′ of FIG. 4 a.
  • FIG. 5 a is a line drawing illustrating the blood level in the air purging chamber relative to the blood level in the venous reservoir at high flow and low volume conditions.
  • FIG. 5 b is a line drawing illustrating the blood level in the air purging chamber relative to the blood level in the venous reservoir at low flow and low volume conditions.
  • FIG. 6 is a line drawing illustrating the air purging chamber used with State-of-the-Art venous bag and an innovative cardiotomy reservoir that limits air from being dragged along its exit tubing into the air purging chamber.
  • FIG. 6 a is a line drawing illustrating the exit tubing into the air purging chamber shown in FIG. 6 and the direction of flow of blood and air bubbles.
  • FIG. 7 is a line drawing illustrating a cardiotomy and a compliant chamber combined as a single unit by sharing a common rigid wall.
  • FIG. 8 a presents data comparing the blood-to-air interface area of the present invention (VR-APC) to that of the State-of-the-Art venous reservoirs as a function of blood volume.
  • VR-APC blood-to-air interface area of the present invention
  • FIG. 8 b presents data comparing the blood-to-air interface area of the present invention (VR-APC) to that of the State-of-the-Art venous reservoirs as a function of the height of the blood in the reservoir.
  • VR-APC blood-to-air interface area of the present invention
  • FIG. 8 c presents the data of FIG. 8 b expanding the lower volume range.
  • FIG. 8 d presents the ratio of the screen area available for venous blood flow to the area of the blood-to-air interface of the present invention (APC and VR+APC) to the State-of-the-Art hard shell venous reservoir.
  • FIG. 1 is a schematic representation of a typical cardiopulmonary bypass circuit according to the prior art showing the location of the venous reservoir relative to the patient and the other components in the circuit.
  • Tubing 123 receiving venous blood from patient 1102 , is coupled to venous reservoir 1103 .
  • the blood is drawn from venous reservoir 1103 via tube 135 by arterial pump 1104 and pumped through membrane oxygenator 1105 wherein oxygen is supplied to the blood and carbon dioxide is removed.
  • the blood from the oxygenator flows via tubing 157 to arterial filter 1107 and then via tubing 172 and an arterial cannula (not shown) back to the patient.
  • One main function of the venous reservoir is to eliminate air contained in the venous blood before it is pumped back to the patient.
  • Suction pump 1114 is usually one of 3 to 5 pumps composing a heart-lung machine, which is part of a hardware required for cardiopulmonary bypass.
  • the defoamed blood is returned from cardiotomy reservoir 1115 back to venous bag 1103 via connecting tubing 153 . As described in the Description of the Prior Art, blood flowing in tubing 153 can entrain air that is then pumped into the venous bag, a non-desirable outcome.
  • FIG. 1 a is a line drawing of State-of-the-Art venous reservoir as typically represented by Cobe's venous reservoir (Model # VRB, Cobe Lakewood, Colo. and described in U.S. Pat. No. 5,352,218, issued to Buckley, et al. Oct. 4, 1994 titled “Venous reservoir bag assembly”). Though this bag has a large screen (defined by the dashed lines in FIG. 1 a ), at low volumes only a very small area of the screen (defined by the double headed arrow in FIG.
  • FIG. 1 a also illustrates that air removal from State-of-the-Art venous reservoirs having at least one pliable wall requires active suction.
  • air is removed with a syringe or usually with one of the roller pumps (e.g. 1114 ) sucking the air out.
  • FIG. 2 is a schematic representation of a system according to present invention showing the relative location of the collapsible venous reservoir in a typical cardiopulmonary bypass circuit and the incorporation of the air purging system.
  • the circuit shown in FIG. 2 is identical to FIG. 1 , except that in FIG. 2 , venous bag 1103 of the present invention incorporates cardiotomy reservoir with chamber 1115 a for “clean” blood and separate chamber 1115 b for “dirty” blood as well as incorporating air purging chamber 1116 .
  • Incorporating the cardiotomy reservoir eliminates the need for tubing 136 between the top of the collapsible venous reservoir and cardiotomy reservoir 1115 and suction pump 1114 required for the prior art systems shown in FIG. 1 .
  • the fluid communication between cardiotomy 1115 a and air purging chamber 1116 can be made, as well known in the art, via perfusion connecting ports and perfusion tubing.
  • FIGS. 3 a and 3 b are line drawings of a front view and top view, respectively, illustrating one preferred embodiment of air purging chamber 1116 .
  • the air purging chamber is a disposable consisting of an inlet chamber and an outlet chamber having a common screened wall. Screen wall 2 c forms at least a portion of the outside wall of inlet chamber 2 and at least a portion of the inside wall of outlet chamber 3 . While there are various configurations that can be used to form the air purging chamber, one of the more efficient and simpler designs is illustrated by FIGS. 3 a and 3 b , and 3 c and 3 d . Blood enters inlet chamber 2 via inlet port 1 .
  • Inlet chamber 2 is a vertical cylinder defined by screened wall 2 c that extends from its bottom level 2 a to its top level 2 b .
  • the internal diameter of chamber 2 preferably is larger than the internal diameter of inlet port 1 .
  • inlet port 1 extends, and expands in diameter into outlet chamber 3 formed by rigid walls 3 c and is sealed to bottom 2 a of inlet chamber 2 to form a continuous fluid path with inlet chamber 2 .
  • the screened walled cylinder forming inlet chamber 2 is housed in, and preferably is centrally located along its axis within a second cylindrical structure formed by rigid vertical wall 3 c forming outlet chamber 3 .
  • Venous blood that contains air bubbles 27 enters air purging chamber 1116 via inlet port 1 into inlet chamber 2 .
  • Bubble movement upward in chamber 2 is enhanced by the larger diameter of inlet chamber 2 relative to that of the inlet port.
  • the large internal diameter reduces the blood velocity thereby reducing drag and allowing longer time for the bubbles to move upward. Lower velocity also lowers the tendency of larger bubbles to break into smaller ones; larger bubbles have higher buoyancy and less of a chance of crossing screen 2 c into outlet chamber 3 . With sufficient pressure across screen 2 c , bubbles can cross into chamber 3 and travel to outlet 4 of chamber 3 , a very undesirable outcome.
  • the upward direction of blood flow at inlet 1 further enhances desirable upward movement of the bubbles. It should be noted that by extending the top most level 2 b of screen 2 c to level 3 b of outlet chamber 3 limits the chance of air crossing into outlet chamber 3 .
  • inlet port 1 can be positioned along top 3 b with a tubing connected to its bottom and extending downward into inlet chamber 2 , much like many of the State-of-the-Art hard shell venous reservoirs.
  • the effective area of screened wall 2 c is defined as the area available for blood in inlet chamber 2 to flow across screen 2 c into outlet chamber 3 .
  • That area equals the product of the periphery of screen wall 2 c (i.e. 3.14 ⁇ diameter of chamber 2 ) and the height difference between blood level 3 d in chamber 3 and bottom level 2 a of chamber 2 . Because none of the screen area in contact with the blood (wetted area) is blocked by the walls 3 c of outlet chamber 3 , as is the case with State-of-the-Art venous bags discussed in reference to FIGS. 1 a , 1 aa and 1 ab , blood flows across that entire wetted area.
  • a larger effective area translates to lower velocity across each pore in the screen which lowers the drag force that can push bubbles across that screen into outlet chamber 3 .
  • Air purging chamber 1116 preferably incorporates defoamer 20 (preferably made of reticulated polyurethane foam having a pore size in the range of 5 to 50 ppi treated with antifoam agents such as silicone) that breaks up foam formed by air traveling up the blood column in inlet chamber 2 .
  • defoamer 20 preferably is located at the top most section of inlet chamber 2 , a location that limits its contact with the blood in chamber 2 but avails it to defoam blood foam that rises to the top of chamber 2 .
  • the defoamer may also incorporate open channel 20 a that provides unrestricted fluid communication between inlet chamber 2 , the top of chamber 3 , and air exhaust port 3 e utilizing structure 20 c .
  • Air is exhausted via channel 3 e in wall 3 c to atmosphere.
  • foam very large bubbles
  • defoamer 20 where it is broken up and collapsed.
  • outlet of channel 3 e directed from exhausting to atmosphere to the inlet of a cardiotomy reservoir, as shown in reference to tube 137 in FIG. 6 , and defoamer 15 cc illustrated in FIGS. 4 a and 4 b where further defoaming can be achieved.
  • Defoamer 20 b preferably has a nominal width equaling to 10% to 50% of the inside periphery of inlet chamber 2 , and extends from the bottom of defoamer 20 , downward up to 75% of the length of inlet chamber 2 . It may also have a smaller surface area than defoamer 20 . These dimensions reduce the undesirable blood contact with the defoamer yet still collapse blood foam that has not reached defoamer 20 and thereby significantly reducing the blood to gas interface associated with foam.
  • variable defoaming capabilities achieved by varying the width to less than the perimeter of chamber 2 and extending the defoamer into the blood chamber accommodates future clinical finding that would optimize which is more beneficial to the patient: collapsing the foam to reduce blood-gas interface or reducing blood contact with the defoamer.
  • air purging chamber 1116 The dimensions of air purging chamber 1116 are balanced between decreasing the velocity of the blood and increasing the screen area to enhance bubble removal (i.e. large internal diameter) and limiting the prime volume (i.e. smaller internal diameter). It should also have low resistance to blood flow. With that in mind, it has been determined that for an air purging chamber designed for adult patients, the optimum internal effective diameter of outlet chamber 3 is between 7 ⁇ 8′′ and 2.0′′ (having a horizontal cross sectional area of 4 to 32 cm 2 ) and inlet chamber 2 preferably has a nominal internal diameter that is 1 ⁇ 8′′ to 3/16′′ smaller than that of the outlet chamber.
  • the effective diameter of the inlet chamber is such that it results in annular cross sectional area (area of the outlet chamber less that of the inlet chamber) of at least 1 cm 2 , or the effective cross sectional area between that of a 3 ⁇ 8′′ ID tubing (0.71 cm 2 ) and that of 1 ⁇ 2′′ ID tubing (1.27 cm 2 ).
  • the preferred cross sectional area of the annular space between the inlet and outlet chamber can also be defined as approximating the cross sectional area of venous line 123 shown in FIG. 2 .
  • the effective diameter is the average diameter of the chamber, (e.g. for an ellipse it would be average of the major and minor diameters).
  • the height of inlet chamber 2 when used in combination with a venous bag, is preferably greater than the maximum blood level in the venous bags, or typically between 7′′ and 22′′.
  • the screen filter is preferably made of medical grade polyester, or from other appropriate blood compatible material, having a pore size between 20 ⁇ and 150 ⁇ but most preferably having a pore size between 20 ⁇ and 40 ⁇ .
  • the outlet chamber has an internal diameter between 1.25′′ and 1.75′′ and a height that prevents blood level 2 d in inlet chamber 2 from contacting defoamer 20 even when the bag is filled. Blood still may contact extended defoamer 20 b .
  • the top of the screen preferably extends to the top of the outlet chamber and may be closed at its top, a design that limits the blood foam crossing the defoamer radially and spilling into the outlet chamber.
  • air purger 1116 When air purger 1116 is used as a stand alone device or in combination with a cardiotomy as for example shown by FIG. 5 a less venous bag 1103 , then it is advantageous to provide it with a larger volume capacity. This can be achieved using the design dictated by the aforementioned dimensionless of the ratio of screen area available for blood flow between the venous inlet and outlet and the blood-to-air interface area. As shown in FIG. 8 d , the largest ratio for State-of-the-Art hard shell venous reservoirs is below 3.
  • the air purger incorporates dimensions, for the adult patient, that provide a ratio that is at least 4 when operating at 100 ml without a complaint venous reservoir and at 300 ml when operating with a complaint venous reservoir.
  • This design allows for a combination of diameters composed of long small diameter at the bottom and a shorter larger diameter at the top. In some respect this design simulates current hard shell venous reservoirs but its much larger ratio renders it superior.
  • a larger volume for the stand alone unit can also be achieved by either having a larger diameter top, as for example shown in FIG. 3 c , or increasing the effective diameter of outlet chamber 3 as its height increases.
  • Typical values for such a unit are illustrated in FIGS. 8 b and 8 c by the data labeled “APC-Compound”.
  • the cross sectional area of these higher volume capacity units still have a blood-to-air interface that is significantly lower than State-of-the-Art venous reservoirs.
  • the venous air purger always provides a blood-to-air interface area that is less than 40 cm 2 for at least the first 10 cm from bottom 3 a of outlet chamber 3 and less than 60 cm 2 for at least the first 14 cm from bottom 3 . Should a higher blood level in chamber 3 lower gravity drainage, then vacuum applied to air exhaust port 3 e compensates for that shortfall.
  • Defoamer 20 preferably has an OD equal to the internal diameter of chamber 2 and a length of 3 ⁇ 4′′ to 6′′. If the defoamer is to be supported by the screen, then the OD of defoamer 20 can be slightly larger than the internal diameter of inlet chamber 2 , thus the slightly compressed defoamer inserted into chamber 2 would spring back and its outer surface grab the inner surface of chamber 2 .
  • the inside diameter of open channel 20 a is preferably between 1 ⁇ 8′′ and 1 ⁇ 2′′, a diameter that allows free air flow yet maximizes the volume of defoamer per unit length.
  • the most preferred dimensions at a prime volume of 100 ml, provide a nominal screen area of 110 cm 2 , a total screen area that is smaller than the most other venous bags (e.g. the screen used in Cobe's bag is 200 cm 2 ).
  • the screen used in Cobe's bag is 200 cm 2 .
  • the preferred screen used for State-of-the-Art venous bags has a pore size of 105 ⁇ with an open area of 52%.
  • the use of smaller pore screen reduces the size and number of bubbles that cross screen 2 c .
  • a test comparing bubble counts at the outlet of the air purging chamber showed that when 130 cc/min of air are pumped into a 6 L/min blood flow entering the venous air purging chamber, the bubble counts of 15 ⁇ size bubbles were 6,410, and 763 bubbles/min for screens having a pore size of 37 ⁇ , 65 ⁇ and 85 ⁇ respectively.
  • the smaller pore size screen had significantly lower bubbles crossing despite its lower open area (31% for the 37 ⁇ , 38% for the 65 ⁇ and 46% for the 85 ⁇ pore size screens).
  • a screen with a pore size of 37 ⁇ having an open area of 31%, the open area per one inch height of screen is over 1.1 in 2 .
  • the screen makes no contact with wall 3 c of outlet chamber 3 , its entire wetted area is available for blood flow. It is the larger effective screen area of the present invention that allows using a smaller pore size screen and still maintaining a total open area that is equal to, or is even larger than, State-of-the-Art venous bags thereby maintaining a blood velocity across the screen that equals to or is lower than that associated with current venous bags. Lower velocity translates to lower number of bubbles crossing the screen.
  • blood outlet chamber 3 preferably is made of clear biocompatible thermoform plastic such as PETG, PVC or polycarbonate or other similar materials.
  • the entire blood contacting surfaces of air purging chamber 1116 , and if possible the defoamer too, are preferably passiviated by one of the many coats available such as the heparin coating by Carmeda (Carmeda AB, Upplands Vasby Sweden.)
  • venous air purging chamber provide a smaller diameter air remover than State-of-the-Art venous or arterial filters and allow the user to operate at a lower blood volume in line with minicircuit technology while providing superior air handling that includes passive air elimination. This is illustrated by FIGS. 8 a , 8 b , 8 c and 8 d.
  • the aforementioned specifications are for illustrative purposes and that other combination of dimensions can also achieve desirable results.
  • the circular cross sections can be replaced with elliptical, star, or rectangular cross sections.
  • the design of the air purging chamber is not limited to the designs shown in FIGS. 3 a and 3 b .
  • the air purging chamber can also be effective by incorporating some of the designs suggested for arterial filters (e.g. U.S. Pat. No. 5,484,474 or 4,743,371) or bubble traps (e.g. U.S. Pat. No. 6,019,824).
  • the air purging chamber can incorporate means assuring that, when inflow exceeds outflow, blood does not overfill reaching and spilling out of exhaust port 3 e .
  • One such means is level sensor 32 b shown in FIG. 3 a .
  • sensor 32 b detects that the blood level in outlet chamber 3 is too high, it sends a signal to alarm the user and/or to controller 33 that increases pump speed to accommodate the increased inflow from the patient and prevent blood overflowing chamber 3 .
  • the controller can also actuate tubing clamp 132 a placed on air exhaust tube 132 shown in FIG. 3 aa to close tube 132 thereby preventing blood from rising to further and spilling.
  • the placement of sensor 32 b can be adjustable to preferably prevent venous blood from contacting main defoamer 20 , but if clinically necessary, moved higher to allow blood level 2 d to reach defoamer 20 but still prevent blood from spilling out.
  • FIG. 3 aa Another and a simpler means that assures blood does not overfill and spills from the air purging chamber is shown in FIG. 3 aa .
  • air exhaust tube 132 extends vertically up so its open end is leveled approximately at the level of the patient's heart.
  • the blood level in the tube 132 rises, reducing gravity drainage (the height difference between the patient and blood level in the air purger) and decreasing venous flow from the patient.
  • Venous inflow stops once the blood level in tube 132 reaches the level of the patient.
  • the internal diameter of tube 132 is preferably at least 3 ⁇ 8′′ but more preferably is at least 1 ⁇ 2′′.
  • the air purging chamber can also incorporate blood level maintaining means for maintaining the blood level in chamber 3 above outlet port 4 thereby preventing gross air (as opposed to microbubbles) from exiting the outlet blood chamber.
  • sensor 32 on wall 3 c operably connected to controller 33 is attached to wall 3 c of outlet chamber 3 in FIGS. 3 a , and 3 aa and is used as a low level sensor that maintains blood level 3 d at a safe level above outlet 4 of chamber 3 .
  • detector 32 senses that the blood level dropped below a safe level, it sends a signal to control unit 33 .
  • Control unit 33 is capable of at least sounding an alarm, slowing down or shutting off the arterial pump, clamping off outflow (e.g.
  • the air purging chamber acts much like a hard shell reservoir except that its blood-to-air interface area and hold up volume are significantly lower.
  • adjustable means to limit the high and low levels of blood in air purger 1116 also allows adjustment of the maximum operating blood volume in outlet chamber 3 and inlet chamber 2 .
  • a small patient requiring low flow and having low blood volume is better served by operating at a low minimum level (low flow allows more time to react before the outlet chamber empties) and a low “high” level setting, the combination minimizing the volume in the air purger.
  • both the low volume and high level sensor would be raised to provide a larger screen area for the higher flow and more volume for the controller to react a low volume condition.
  • inlet pressure sensed by pressure transducer 32 ca shown in FIG. 3 aa can send a signal to control unit 33 that controls pump speed in a manner similar to that described level sensor 32 .
  • a low hydraulic pressure sensed at 32 ca indicates a low blood level in outlet chamber 3 and signals controller 33 to react to prevent further drop in blood level.
  • a second pressure transducer, 32 cb measuring the vacuum applied to the blood chamber, is also used.
  • the signal used for controller 33 is the difference between transducer 32 ca and transducer 32 cb , the difference being the hydraulic pressure due to the blood level in the chamber.
  • FIGS. 3 c and 3 d illustrate an air purging reservoir incorporating means to accept vented (“clean”) blood. Combining the vented blood directly with the venous blood in chamber 2 is prohibitive because the high volume of air in the vented blood would cause excess foaming. Incorporating an air purging chamber for vented blood at the top of the air purging chamber assures that the large volume of air, so common to vented blood, is eliminated prior to the vented blood combining with the blood in inlet chamber 2 . As shown, the top section of the air purging chamber is radially enlarged preferably to 1.5 to 2.5 times the diameter of chamber 3 so channel 20 a can accommodate vent chamber 22 .
  • Vent chamber 22 is formed of screen wall 22 c , much like chamber 2 is formed by screen wall 2 c , and incorporates defoamer 15 at the top section of chamber 22 .
  • Vent chamber 22 is housed in the enlarged top section of outlet chamber 3 defined by outside cylindrical wall 3 cc inside cylindrical screen wall 2 cc .
  • Defoamer 20 is contained and may be supported by screen 2 cc .
  • Vent chamber is centrally suspended at the top and preferably does not contact venous blood defoamer 20 .
  • Annular channel 20 a between vent chamber 22 and venous defoamer 20 serves to exhaust venous air.
  • Defoamer 20 is supported by circular screen 2 cc and defoamer 15 is supported by screen 22 c .
  • the lower section of air purging chamber 1116 a is identical to that described for air purging chamber 1116 in reference to FIG. 3 a .
  • Inlet chamber 2 forms unobstructed fluid communication with enlarged channel 20 a via thin walled fitting 24 .
  • screen 2 c is sealed to the smaller diameter bottom section of fitting 24 and screen 2 cc is sealed to the larger diameter top section of fitting 24 .
  • Path 22 b prevents, or at least reduces, splashing where the vented blood enters blood in chamber 2 and combines with venous blood at level 2 d . Less splashing results in less air bubbles entrapment and foam formation.
  • Path 22 b can be for example polyurethane foam as used for defoamer 20 but without the antifoam agents. Other materials that wick blood and prevent its free fall, such as screens, can also serve as the fluid path. Air entering inlet chamber 2 crosses to outlet chamber 3 along a non wetted screen area and then flows upward to air exhaust tube 3 e .
  • defoamer 15 may also facilitate defoaming venous blood foam formed in chamber 2 .
  • FIG. 3 e illustrates air purger 1116 a , shown in FIG. 3 c , in its preferred tilted angle of between 10° and 45° and most preferably between 15° and 30°.
  • Angling the air purger allows air bubbles 27 to separate from the blood and move vertically up to higher wall 2 c -H and the blood to lower wall 2 c -L.
  • fluid path 22 b is in contact with screen wall 2 c -L. This allows vented blood flowing along path 22 b , to continue flowing along screen wall 2 c -L thereby further reducing splashing of vented blood as it combines with venous blood in chamber 2 at level 2 d.
  • FIG. 3 c also illustrates that a design where bottom 3 a of outlet chamber 3 and bottom 2 a of inlet chamber 2 can essentially be at the same vertical height.
  • This design reduces the dead space associated with that shown in FIG. 3 a where some blood can always be left in inlet tube 1 because its opening is higher than outlet port 4 .
  • outlet port 4 has expanded section 4 c about the area of screen 2 c at bottom 3 a of outlet chamber 3 to provide slower and more uniform velocity.
  • Such a design would require that chamber 3 be formed by blow molding or combined by two halves made by vacuum forming or that outlet port be injected molded as a separate piece and fixed to the bottom of chamber 3 .
  • Outlet Port 4 can also be aligned parallel to inlet port 1 .
  • FIG. 4 a is a line drawing illustrating a front view of a unit combining air purging chamber 1116 with compliant venous reservoir 1103 having at least one pliable wall. As shown, the unit also incorporates dual chamber cardiotomy reservoir ( 1115 a and 1115 b in FIG. 2 ). A line drawing of a cross sectional view of the combined unit shown in FIG. 4 a taken along line 4 b - 4 b ′ is illustrated in FIG. 4 b .
  • FIG. 4 c A line drawing of a cross sectional view of the combined unit shown in FIG. 4 a taken along line 4 c - 4 c ′ is illustrated in FIG. 4 c .
  • FIG. 4 d A line drawing of a cross sectional view of the combined unit shown in FIG. 4 a taken along line 4 d - 4 d ′ is illustrated in FIG. 4 d .
  • inlet channel 1 a extends from top inlet 1 of the combined unit downward to form a fluid communication with inlet chamber 2 of air purging chamber 1116 .
  • Air purging chamber 1116 is essentially the same as described in reference to FIGS. 3 a and 3 b .
  • Outlet 4 of outlet chamber 3 extends as channel 4 b to form fluid communication with inlet 5 of compliant storage chamber 7 .
  • Compliant storage chamber 7 is formed by rigid concaved backwall 8 c and matching in shape concaved pliable diaphragm 25 , seen in FIGS. 4 c and 4 d .
  • Diaphragm 25 which can be vacuum-formed from films such as PVC, polyurethane or EVA, nestles in concaved backwall 8 c and is sealed along its outside periphery to the outside periphery of rigid wall 8 c to form variable volume closed blood chamber 7 .
  • Chamber 7 has an inlet port 5 and outlet port 6 , both located along bottom 7 a of blood chamber 7 as illustrated in FIGS.
  • Blood is pumped from blood chamber 7 via outlet 6 that is in fluid communication with arterial pump 1104 , shown in FIG. 2 , via typical perfusion tubing (e.g. tube 135 in FIG. 2 ).
  • typical perfusion tubing e.g. tube 135 in FIG. 2
  • pliable diaphragm 25 moves outward, expanding the volume capacity of chamber 7 to accommodate the additional blood volume.
  • the only air to be removed from chamber 7 is that associated with initial priming of chamber 7 .
  • Air in blood chamber 7 is removed through tube 37 , shown in FIG. 4 d , having one open end along top 7 b of chamber 7 and the other open end accessible for the user to pull the air out.
  • a one-way valve or a stopcock can be adapted to tube 37 to facilitate air removal and preventing its return.
  • Air movement upward in chamber 7 may be enhanced by at least one protrusion 8 ca incorporated into rigid backwall 8 c , shown in FIGS. 4 a and 4 c .
  • the protrusion serves the same purpose as described in reference to air removal tubes shown in FIG. 1 b of aforementioned Tamari's U.S. Pat. No. '426.
  • protrusion 8 ca forms channels between its wall and flexible diaphragm 25 to allow air to move up and be purged via air purging port 37 .
  • protrusions 8 ca also provide greater strength and stiffness to backwall 8 c , thereby allowing wall 8 c to be thinner, reducing its weight and cost. As described below, once primed and air free, no air should enter blood chamber 7 , a great advantage over State-of-the-Art venous bags which require constant vigilance, suction to remove that air or some automated means.
  • compliant chamber 7 The preferred dimensions of compliant chamber 7 depend on its use. For adult patients, the blood volume capacity should be between 1 and 3 liters, but can be reduced to 20 to 500 ml when designed to be used in association with minicircuits. The lowest volume is that required for chamber 7 to provide the shot-off feature of outlet 6 of the compliant chamber 7 described below.
  • a critical design feature of the combining air purging chamber 1116 with venous reservoir 1103 is that the vertical location of outlet port 4 of the air purging chamber 1116 is below the lowest vertical location of chamber 7 of venous reservoir 1103 .
  • Height difference “y 1 ” shown in FIG. 4 a between top of outlet port 4 and bottom of outlet port 6 should be sufficient to assure that as blood level 3 d of chamber 3 drops below the bottom of outlet 6 of blood chamber 7 , the negative pressure due to the hydraulic height difference between blood level 3 d and the bottom of outlet 6 is sufficient to cause pliable diaphragm 25 , shown in FIGS. 4 c and 4 d , to collapse against backwall 8 and close outlet 6 .
  • Closed port 6 isolates outlet chamber 3 from the negative pressure generated by pump 1104 , shown in FIG. 2 and stops flow out of compliant chamber 7 , thereby stops flow out of chamber 3 via outlet port 4 preventing blood level 3 d from dropping to outlet port 4 and air flowing from emptied blood chamber 3 into blood chamber 7 of venous reservoir 1103 .
  • blood level 3 d in air purger chamber 3 rises above bottom 7 a of complaint chamber 7 , then blood starts to refill compliant chamber 7 until its outlet 6 reopens.
  • FIGS. 4 a - d and 5 a - b provides automatic and passive air purging capabilities, as does a hard shell venous reservoir and the clinically preferred close blood chamber as does a soft shell venous reservoir. It also prevents air from entering the compliant venous blood chamber. Any other venous bag that contains air, allows that air to be pumped to the patient when it is drained of blood. With the aforementioned combined unit, air purging is handed in a separate chamber than compliant chamber 7 forming the closed venous reservoir and therefore no air can be pumped to the patient.
  • the lower section of compliant storage chamber 7 that between bottom 7 a and transition level 7 c in FIGS. 4 a and 4 d having a height of “h”, is shallower, more vertical in shape, and accommodates much less volume per height than the upper section, that between transition 7 c and upper level 7 b , defined as “H-h” in FIG. 4 d .
  • the shallower section provides a larger change in height per unit change in blood volume and therefore a better visualization of small volume changes in that section.
  • the larger increase in blood height also results in a greater force to move compliant diaphragm 25 from a closed position to an open position thereby overcoming the shortfall of prior art venous reservoir as previously described for aforementioned U.S. Pat. No. 4,424,190.
  • outlet port 6 located on lower rigid wall 8 cb that is flat and close to vertical (e.g. between 70° and 90° of the horizontal plane).
  • the vertical shape allows diaphragm 25 more easily to “peel” away from rigid wall 8 cb shown in FIG. 4 d .
  • the depth of the lower section is preferably between 1 ⁇ 4′′ and 1′′ and most preferably between 3 ⁇ 8′′ and 5 ⁇ 8′′. Height “h” of the lower section is preferably between 1′′ and 4′′ but can be higher if a low volume compliant storage chamber is desired to better meet minicircuit requirements.
  • outlet 6 of chamber 7 is not located at the lowest fluid level of chamber 7 , as is the case for prior art compliant venous reservoirs, but preferably at least 1 to 4 lengths of the diameter for outlet port 6 away from bottom 7 a .
  • This design also enhances intimate contact between diaphragm 25 and rigid backplate 8 and improves the closure of outlet port 6 .
  • compliant chamber 7 can be limited in volume by reducing the chamber to that defined by a height sufficient to allow diaphragm 25 to remain open at the designed blood flows (e.g. 6 liters/min for adult patients) and a blood level in outlet chamber 3 that provides sufficient screen area for efficient air removal.
  • the minimum volume that is needed for minicircuits would have compliant chamber 7 serve as a shut off valve to assure that blood flow from air purging chamber to complaint chamber 7 stops prior to air exiting outlet port 4 of outlet chamber 3 .
  • the minimum operating volume of the compliant chamber is preferably between 20 ml and 200 ml.
  • blood level 3 d can rise above the vertical height of “h” (the maximum height for compliant chamber 7 when used only as a shut off valve) it will provide a higher hydraulic pressure than that afforded by “h”. This higher pressure will result in a higher force available to reopen port 6 without the large volume associated with filling section “H-h” shown in FIG. 4 d.
  • a decrease in the screen area results in an increase in blood velocity across each pore of the screen which can cause more bubbles at the inlet side of the screen to cross to the outlet side of the screen.
  • the screened section in the air purging chamber can extend below the bottom of compliant storage chamber 7 , assuring that even at very low blood levels in compliant storage chamber 7 , the blood column in the air purging chamber is high enough to provide a large screen area to inhibit bubbles in the venous line from reaching the outlet of the compliant storage chamber.
  • FIGS. 4 a , 5 a , 5 b and 6 where bottom 2 a of screen inlet chamber 2 is vertically lower than bottom 7 a of blood chamber 7 .
  • Another advantage is that whenever blood flows from the air purging chamber to the compliant storage chamber, the height of the blood column in the air purging chamber is always higher than the blood level in the compliant storage chamber.
  • FIGS. 5 a and 5 b are line drawings illustrating the design superiority of the present invention in handling air.
  • air purging chamber 1116 is combined with venous reservoir 1103 in a similar manner to the combined air purging chamber 1116 and venous reservoir 1103 as described in reference to FIGS. 4 a , 4 c and 4 d .
  • Cardiotomy chambers 1115 a and 1115 b shown in FIGS. 5 a and 5 b do not affect the discussion below.
  • FIG. 5 a illustrates a condition that is most challenging to any venous reservoir: eliminate incoming venous air at low blood volume and high blood flow.
  • bottom 2 a of screen 2 c forming cylindrical inlet chamber 2 can be located below bottom 7 a of blood chamber 7 .
  • the height difference between bottom 2 a and bottom 7 a provides additional screen area with a smaller increase in operating volume than that possible with State-of-the-Art venous bags.
  • the blood volume where air is eliminated i.e.
  • chamber 2 is present as a tall vertical blood column surrounded by screened wall 2 c provides a larger uninhibited screen area than the shallow but wide blood level of the aforementioned state-of-art venous bags that exposes a much smaller effective screen area as described in reference to FIGS. 1 a , 1 aa , and 1 ab .
  • blood level 3 d is higher than blood level 7 d in blood chamber 7 of venous reservoir 1103 (i.e. the pressure required to overcome the aforementioned resistance to flow).
  • the difference in height between blood level 3 d in air purging chamber 1116 and blood level 7 d in venous reservoir 1103 increases as blood flow increases as is illustrated by comparing low flow conditions illustrated in FIG. 5 b to high flow conditions illustrated in FIG. 5 a .
  • This inherent property provides additional safety: at higher flows when a fixed screen area is more vulnerable to bubbles crossing the screen (higher velocity and drag), the current invention presents a larger screen area for blood flow at least partially compensating for the higher flow and keeping the velocity across each pore low.
  • channel 4 b could incorporate an adjustable resistance that controls the height of level 3 d relative to level 7 d .
  • the resistance to flow between chamber 3 and chamber 7 can be increased to maintain higher blood level 3 d .
  • the resistance to flow between chamber 3 and chamber 7 can be decreased because blood level 3 d is already high. This can be achieved by incorporating an adjustable resistance, to the flow fluid path between the air purging chamber and compliant storage chamber 7 , such as tubing clamp 4 bb shown in FIG.
  • FIGS. 5 a and 5 b also illustrate that interconnecting channel 4 b could form U-shape bottom 4 a having a vertical level that is lower than the level of outlet 4 .
  • Lower level 4 a provides a higher hydraulic pressure to close outlet 6 by pliable film 25 when blood level 3 d drops below the level of outlet port 6 , as described in reference to FIGS. 4 a and 4 d .
  • lowest level 4 a is lower than the bottom of outlet 6 of blood chamber 7 , then the vertical height of outlet 4 of outlet chamber 3 can be raised above outlet 6 .
  • FIG. 5 b illustrates another innovation of the present system; when air purger 1116 is combined with compliant venous reservoir 1103 , then interconnecting tube 4 b can incorporate one more port in fluid communication via tube 4 c with outlet port 6 of reservoir 1103 . Tube 4 c is also in fluid communication with outlet port 6 a . This combination allows the user to clamp outlet port 6 and interconnecting tube 4 b (between tube 4 c and inlet 5 of reservoir 1103 ) thereby bypassing reservoir 1103 . Bypassing reservoir 1103 allows flowing at a lower operating volume. Thus, one device allows the use of only the venous air purger for cases that do not require much external blood volume capacity (e.g. routine coronary bypass cases) thereby minimizing prime and operating volume. For cases where a large volume capacity is required, tube 4 c is clamped between tube 4 b and outlet 6 a thereby having venous blood flowing through and using the capacity of complaint reservoir 1103 .
  • external blood volume capacity e.g. routine coronary bypass cases
  • FIG. 8 a illustrates that the blood-to-air interface area of the combination of the complaint venous reservoir and venous air purger (APC-VR) is unaffected by the blood volume in the venous bag and is much lower than State-of-the-Art hard shell venous reservoirs.
  • APC-VR venous air purger
  • the area of the blood-to-air interface of the air purging chamber having the most preferred dimensions is only between 8 and 15 cm 2 compared to 180 cm 2 to 305 cm 2 for State-of-the-Art hard shell reservoir.
  • the area of the blood to gas interface of the air purging chamber remains between 8 cm and 15 cm 2 as compared to an area from 78 cm 2 to 305 cm 2 for the State-of-the-Art hard shell venous reservoir shown in Table 1. This significant reduction in blood-gas interface results in significant reduction in blood damage and should translate to better clinical outcome.
  • the blood-to-air interface area for the stand alone venous air purger is also a lower than that of the State-of-the-Art venous reservoirs.
  • the blood-to-air interface area for the former being no more than 50 cm 2 at a volume of 500 ml and no more than 80 cm 2 at a volume of 800 ml.
  • FIGS. 4 a - 4 d also illustrate another permutation possible with the present invention: a unitized air purging chamber 1116 , compliant blood chamber 7 forming venous reservoir 1103 and a two-chamber (“clean” blood chamber 1115 a and “dirty” blood chamber 1115 b ) cardiotomy reservoir.
  • the two-chamber cardiotomy reservoir shown is for illustrative purposes only. Essentially it is similar to many of the cardiotomy reservoirs in the market (e.g. see cardiotomy reservoir 4 shown in FIG. 1 of aforementioned U.S. Pat. No. 6,287,270) except that it provides clean blood chamber 10 a and dirty blood chamber 10 b , separated by wall 16 .
  • Cardiotomy section for dirty blood 1115 b has at least one inlet port 11 a that accepts sucker blood and directs that blood to cardiotomy filter 11 composed of defoamer and a screen and/or felt 11 c to filter debris and air associated with suction blood.
  • the filtered blood then accumulates in chamber 10 b .
  • Cardiotomy section for clean blood 1115 a separates air from the vented blood; it does not need aggressive filter 11 used for dirty blood chamber 10 b .
  • the blood filtered in this chamber is “clean”, there is no need to store it, and it can be combined with venous blood without concerns for the inflammatory response associated with the dirty blood in chamber 10 b .
  • Defoamer 15 used to collapse foam formed by the air in the clean blood in chamber 10 a can be much smaller, for example 20% in volume of the defoamer in filter 11 of chamber 10 b .
  • Inlet port 15 a of clean blood cardiotomy 1115 a accepts clean blood and directs it to closed chamber 14 formed, at least partially, by screen wall 14 c .
  • chamber 14 is angled, as shown in FIG. 4 d , a design that has the advantages described by the following example: if the walls of inlet chamber 14 are formed by screen 14 c , then air is separated from the blood by having the blood flow across the lower portion of screen 14 c while air is removed along the top section of the screen.
  • the pore size of screen 14 c is sufficiently small to assure that blood wicks and flows along wall 14 c till it reaches bottom 14 ca , or blood accumulating in chamber 10 , rather than dripping across the screen. This limits splashing and the previously described negative results associated with splashing.
  • Defoamer 15 located along the top section of screened chamber 14 preferably does not contact blood flowing along the lower wall of chamber 14 but is available to collapse blood foam rising to it.
  • the filter for the clean blood is similar to that described in reference to inlet chamber 2 shown in FIGS. 3 a and 3 b with the exception that the inlet for chamber 14 is at the top.
  • Channel 19 forming the fluid communication between the bottom of the cardiotomy and the inlet to the air purger is preferably angled to reduce blood velocity as well as allow air bubbles to rise to the top of the moving column as explained in detail in reference to yet to be described channel 153 shown in FIGS. 6 and 6 a .
  • the entrance to channel 19 , at the bottom of chamber 10 a is widened as indicated by 19 b in FIGS. 4 a and 4 b , a design that allows air bubbles in channel 19 to separate from the flowing blood and escape and thereby limit the air volume trapped as clean blood intermittently flows down channel 19 .
  • Channel 19 should have at least the top portion enlarged to an equivalent diameter greater than 3 ⁇ 8′′ and preferably at least 1 ⁇ 2′′.
  • Blood velocity in channel 19 can also be reduced by structure 19 c , that can be for example polyurethane foam as used for defoamer 20 but without an antifoam agent. Reducing the blood velocity in channel 19 reduces air bubbles entrapment, especially at the level where the flowing vented blood combines with the blood at the lower level, and foam formation in channel 19 .
  • structure 19 c can be for example polyurethane foam as used for defoamer 20 but without an antifoam agent.
  • Reducing the blood velocity in channel 19 reduces air bubbles entrapment, especially at the level where the flowing vented blood combines with the blood at the lower level, and foam formation in channel 19 .
  • lowest level 19 a of channel 19 and lowest level 1 aa of inlet channel 1 a are lower than level 1 ab where channel 19 and channel 1 a combine and the deaerated vented blood combines with the venous blood.
  • Chambers 10 a and 10 b are in fluid communication along their common top wall via always open channel 16 a and along their common floor via ports 17 and 18 .
  • Ports 17 and 18 are in fluid communication, for example via tubing 13 , that can be closed or opened with valve 13 a to allow, or prevent, flow of dirty blood into clean chamber 10 a and then to combine with the venous blood in chamber 2 .
  • valve 13 a is a sliding tubing clamp. Dirty blood accumulated in the chamber 10 b blood can be removed via port 21 a atop chamber 10 b , through tubing 21 aa with its open end at the bottom of chamber 10 b.
  • the volume of chambers 1115 a and 1115 b can be between 1.0 and 1.5 liters, but preferably, the volume of clean blood chamber 1115 a is greater than dirty chamber 1115 b .
  • This distribution provides a larger capacity to store venous blood that may overflow from venous reservoir 1103 without that blood contacting filter 11 of dirty chamber 1115 b.
  • At least two of the three units: air purging chamber, compliant chamber and cardiotomy chamber can be combined to form a single unit.
  • air purging chamber compliant chamber
  • cardiotomy chamber can be combined to form a single unit.
  • the combination unit consists of venous reservoir 7103 having at least one flexible wall and one rigid wall, said walls sealed along their outside periphery to form closed complaint chamber 707 much like compliant chamber 7 previously described in reference to FIGS. 4 a - 4 d .
  • Venous blood enters chamber 707 via inlet port 701 and exits via outlet port 706 , both preferably located along bottom 707 a of chamber 707 .
  • Air entrained in the venous blood is purged via air purging port 703 located along the top most point in chamber 707 and preferably in fluid communication with chambers 710 a and 710 b of clean and dirty cardiotomies respectfully.
  • Channel 703 preferably extends up to the top of the cardiotomy reservoir.
  • Channel 703 preferably is large in diameter (e.g. 1 ⁇ 2′′ ID) to form a low resistance channel for air bubbles to move up the blood column in channel 703 .
  • Defoamer 720 may be located along the top 707 b of compliant chamber 707 and may also extend into air purging port 703 (shown as 720 a ).
  • Air sensor 732 may also be added for the same purpose and function as previously described in reference to sensor 32 in FIGS.
  • FIG. 7 shows that outlet port 706 is located in the lower portion of chamber 707 and is designed with considerations previously described for outlet 6 shown in reference to FIGS. 4 a - 4 d .
  • level 719 a is vertically lower than outlet port 706 . This assures that outlet port 706 closes prior to blood level 719 d in channel 719 drops to lowest point 719 a of channel 719 .
  • the unit shown in FIG. 7 does not have an air purger such as 1116 shown in FIG. 6 . It therefore does incorporate a screen (not shown) between inlet port 705 and outlet port 706 .
  • the dual chamber cardiotomy reservoir atop the venous reservoir is almost identical to that described in reference to clean 1115 a and dirty 1115 b blood chambers shown in FIGS. 4 a - 4 d . It has one large chamber 710 divided by separating wall 716 into chamber 710 a for clean blood and chamber 710 b for dirty blood. Wall 716 extends from the bottom to the top of chamber 710 leaving a fluid communication 716 a between the top of chambers 710 a and 710 b . Since clean blood need not be kept out of closed compliant chamber 707 , then the volume of chamber 710 a need only be sufficient to accommodate the screened chamber 714 used to deaerate and defoam the clean blood.
  • the volume of chamber 710 a should be no more than 20%, of the volume of chamber 710 b .
  • Clean blood enters via port 715 a into clean chamber 714 formed of screen wall 714 c that is sealed at its bottom. Defoamer 715 positioned at the top section of chamber 714 collapses foam in chamber 714 . Clean blood flows through screen 714 c , with the screen reducing the bubble size and air volume in the exiting clean blood.
  • dirty blood enters via port 711 a into aggressive filter 711 that also includes a defoaming agent.
  • the filtered dirty blood flows into chamber 710 b where it can be stored or flow to chamber 710 a via port 718 and 717 .
  • Ports 717 and 718 are in fluid communication via tubing 713 that can be closed or opened with valve 713 a to allow or prevent the dirty blood to flow to clean chamber 710 a and then to combine with the venous blood in chamber 707 .
  • Blood in chamber 710 a flows down channel 719 and combines with venous blood at inlet port 701 .
  • lowest vertical level 719 a of channel 719 is lower than inlet port 701 and that inlet port 701 is bottom 707 a of chamber 707 . This minimizes air from the venous blood rising into channel 719 or air from channel 719 rising up venous line via inlet port 701 .
  • clean blood chamber 1115 a larger than dirty blood 1115 b , for example for patients with a large blood volume that needs to be stored without it contacting the filter of the dirty blood.
  • FIGS. 4 c and 4 d also illustrate that compliant blood chamber 7 can be fitted with front plate 28 sealed along the outside periphery of wall 8 c to form sealed air chamber 26 with flexible diaphragm 25 as one wall and front plate 28 as the other wall.
  • Channel 12 forms a fluid communication between air chamber 26 at opening 12 a and cardiotomy reservoir chamber 10 at opening 12 b assuring that the air pressure in these two chambers is equal.
  • Exhaust port 21 in fluid communication with chamber 10 is open to ambient atmosphere, or as shown in FIG. 4 d , in fluid communication with vacuum regulator 29 . The latter can be used for vacuum assisted venous return (VAVD).
  • VAVD vacuum assisted venous return
  • exhaust port 21 is in fluid communication with the air side of chamber 10 a of the clean blood, chamber 10 b of the dirty blood, and inlet chamber 2 and outlet chamber 3 of the air purging chamber. It is also in fluid communication with the air side of diaphragm 25 . This allows a single port to apply vacuum to all four chambers. Freely moving compliant diaphragm 25 assures that the blood pressure in compliant storage chamber 7 equals the air pressure in air chamber 26 . Thus, when vacuum is applied to port 21 , it is transmitted to air chamber 10 , and then via channel 12 , to air chamber 26 and then, to the air side of moving diaphragm 25 , to the blood side of diaphragm 25 forming the flexible wall of chamber 7 .
  • vacuum can be applied to flexible diaphragm 25 that allows vacuum assisted venous drainage (VAVD).
  • VAVD vacuum assisted venous drainage
  • the shape of front plate 28 preferably is similar in shape to the shape of diaphragm 25 thereby allowing diaphragm 25 to fully expand and maximize the volume chamber 7 can fill to with blood.
  • the same vacuum is also applied to inlet chamber 2 and outlet chamber 3 of air purging chamber 1116 via channel 3 e shown in FIGS. 4 a and 5 a and 5 b .
  • the unrestricted fluid communication between air chamber 26 and cardiotomy chamber 10 and between cardiotomy chamber and inlet chamber 2 and outlet chamber 3 of air purging chamber 1116 (or 1116 a ) allows a single air port in any of these chambers to be used to apply vacuum to the other chambers and maintain these other chambers at the same vacuum as the chamber with that single air port.
  • port is port 21 atop chamber 10 of cardiotomy 111 a shown in FIGS. 4 a , 4 b and 4 d.
  • FIGS. 4 a and 4 d show another innovation: a vapor trap incorporated into the reservoir designed for VAVD.
  • bottom section 21 b of exhaust port 21 extends below the top of chamber 12 .
  • the top of chamber 12 is in fluid communication with the air space above clean chamber 1115 a and dirty chamber 1115 b and the bottom of chamber 12 is in fluid communication with air chamber 26 of venous reservoir 1103 .
  • any water condensate that drips down out of exhaust tube 21 b falls into, and is trapped by, chamber 12 and eventually flows into air chamber 26 of venous reservoir 1103 .
  • air purging chamber 1116 , venous reservoir 1103 , cardiotomy reservoir 1115 , as well as channels 1 , 3 e , 4 and 12 interconnecting these chambers, are at least partially formed with common rigid plate 8 , a design that reduces manufacturing costs and simplifies setup.
  • rigid wall 8 a forms at least a part of the wall forming inlet channel 1 a of air purging chamber 1116 ; rigid wall 8 b forms at least one part of the wall forming outlet chamber 3 of air purging chamber 1116 ; rigid wall 8 c forms at least a part of the wall forming compliant storage chamber 7 ; rigid wall 8 d forms at least a part of channel 4 b connecting outlet chamber 3 to compliant storage chamber 7 ; rigid wall 8 e forms channel 19 connecting chamber 10 of cardiotomy 1115 to the bottom of inlet channel 1 ; rigid wall 8 f forms at least one part of the wall forming chamber 10 of cardiotomy 1115 .
  • Common wall 8 may also form channel 3 e connecting the top of outlet chamber 3 to the top chamber 10 of cardiotomy 1115 , outlet port 6 of compliant storage chamber 7 as well as the numerous connectors atop cardiotomy reservoir 1115 .
  • rigid wall 8 can have a matching clamshell like mirror image structure that fits to complete the walls required to form the aforementioned chambers and channels.
  • Other designs include having outlet chamber 3 and cardiotomy chamber 10 with its divider 16 , and concave section 8 c injected molded and then fitted with top covers that incorporate ports such as air port 21 or inlet port 1 a shown in FIG. 4 a.
  • FIG. 6 is a line drawing illustrating a design where tubing is used as channel 4 b connecting outlet 4 of the air purging chamber, previously described in reference to FIGS. 3 a - 3 d , to compliant reservoir 7 , and tubing 153 is used to connect the outlet of cardiotomy reservoir to inlet 1 of air purging chamber 1116 .
  • tubing has two advantages: it simplifies the mold and it enables the user to clamp off the tubing when needed. It also illustrates that air purging chamber 1116 can be used with State-of-the-Art venous bags eliminating air from entering the bag to provide greater safety.
  • FIG. 6 also illustrates another means to reduce air being dragged from cardiotomy 1115 to inlet chamber 2 via channel 153 .
  • tube 153 is slanted to allow air bubbles 27 that have entered tube 153 to rise to the radial top of channel 153 and then, as illustrated in FIG. 6 a by the upward pointing arrow, move up channel 153 along its top most wall.
  • Raised section 159 a of outlet port 159 located at the bottom of cardiotomy 1115 facilitates air bubble escape from channel 153 by preventing blood from entering channel 153 at highest outlet point 159 a where air escapes from tube 153 during intermittent blood flow.
  • channel 153 should have at least its top portion enlarged to an equivalent diameter greater than 3 ⁇ 8′′ and preferably at least 1 ⁇ 2′′ and incorporate structure 153 c serving the same function as structure 19 c previously described in reference to FIG. 4 a.

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WO2006057650A2 (fr) 2006-06-01
EP2335751B1 (fr) 2016-04-06
EP1720585A2 (fr) 2006-11-15
EP1720585A4 (fr) 2008-12-31
WO2006057650A3 (fr) 2006-10-12
EP2335751A2 (fr) 2011-06-22
EP2335751A3 (fr) 2011-09-28

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